impact of solar radiation on chemical structure and
TRANSCRIPT
Impact of Solar Radiation on Chemical Structureand Micromechanical Properties of Cellulose-BasedHumidity-Sensing Material CottonidRonja Scholz ( [email protected] )
Technische Universitat Dortmund https://orcid.org/0000-0001-9872-977XMatthias Langhansl
Technical University Munich: Technische Universitat MunchenMoritz Hemmerich
Hochschule Hamm-LippstadtJörg Meyer
Hochschule Hamm-LippstadtCordt Zollfrank
Technische Universität München: Technische Universitat MunchenFrank Walther
Technische Universität Dortmund: Technische Universitat Dortmund
Research
Keywords: solar radiation, chemical structure, Cottonid, humidity-sensing material
Posted Date: October 19th, 2020
DOI: https://doi.org/10.21203/rs.3.rs-93091/v1
License: This work is licensed under a Creative Commons Attribution 4.0 International License. Read Full License
Version of Record: A version of this preprint was published at Functional Composite Materials on April6th, 2021. See the published version at https://doi.org/10.1186/s42252-021-00022-4.
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Impact of solar radiation on chemical structure and micromechanical properties of 1
cellulose-based humidity-sensing material Cottonid 2
3
R. Scholz1,*, M. Langhansl2, M. Hemmerich3, J. Meyer3, C. Zollfrank2, F. Walther1 4
5
1Department of Materials Test Engineering (WPT), TU Dortmund University, Baroper Str. 303, D-6
44227 Dortmund, Germany ([email protected], [email protected]) 7
8
2Biogenic Polymers, TUM Campus Straubing for Biotechnology and Sustainability, Schulgasse 9
16, D-94315 Straubing, Germany 10
11
3Photonics and Material Science, Hamm-Lippstadt University of Applied Science, Marker Allee 12
76-78, D-59063 Hamm, Germany 13
14
*corresponding author 15
16
Abstract 17
Renewable and environmentally responsive materials are an energy- and resource-efficient 18
approach in terms of civil engineering applications, e.g. as so-called smart building skins. To 19
evaluate the influence of different environmental stimuli, like humidity or solar radiation, on the 20
long-term actuation behavior and mechanical robustness of these materials, it is necessary to 21
precisely characterize the magnitude and range of stimuli that trigger reactions and the resulting 22
kinetics of a material, respectively, with suitable testing equipment and techniques. The overall 23
aim is to correlate actuation potential and mechanical properties with process- or application-24
oriented parameters in terms of demand-oriented stimuli-responsive element production. In this 25
study, the impact of solar radiation as environmental trigger on the cellulose-based humidity-26
sensing material Cottonid, which is a promising candidate for adaptive and autonomously moving 27
elements, was investigated. For simulating solar radiation in the lab, specimens were exposed to 28
2
short-wavelength blue light as well as a standardized artificial solar irradiation (CIE Solar ID65) in 29
long-term aging experiments. Photodegradation behavior was analyzed by Fourier-transform 30
infrared as well as electron paramagnetic resonance spectroscopy measurements to assess 31
changes in Cottonid’s chemical composition. Subsequently, changes in micromechanical 32
properties on the respective specimens’ surface were investigated with roughness measurements 33
and ultra-micro-hardness tests to characterize variations in stiffness distribution in comparison to 34
the initial condition. Also, thermal effects during long-term aging were considered and contrasted 35
to pure radiative effects. In addition, to investigate the influence of process-related parameters on 36
Cottonid’s humidity-driven deformation behavior, actuation tests were performed in an alternating 37
climate chamber using a customized specimen holder, instrumented with digital image correlation 38
(DIC). DIC was used for precise actuation strain measurements to comparatively evaluate 39
different influences on the material’s sorption behavior. The infrared absorbance spectra of 40
different aging states of irradiated Cottonid show decreased absorption at 2,900 cm-1, i.e. the 41
spectral region of C - H stretching vibrations, and increased absorption at 1,800-1,700 cm-1, i.e. 42
the spectral region of C = O stretching vibrations, with respect to unaged samples and therefore 43
indicate oxidative stress on the surface. These findings differ under pure thermal loads. EPR 44
spectra could corroborate these findings as radicals were detected, which were attributed to 45
oxidation processes. Instrumented actuation experiments revealed the influence of processing-46
related parameters on the sorption behavior of the tested and structurally optimized Cottonid 47
variant. Experimental data supports the definition of an optimal process window for stimuli-48
responsive element production. Based on these results, tailor-made functional materials shall be 49
generated in the future where stimuli-responsiveness can be adjusted through the manufacturing 50
process. 51
52
1. Introduction and state of the art 53
Stimuli-responsive materials inspired by the natural behavior of biological structures, like plants, 54
are adaptive elements in various applications, viz. in biomedicine for drug delivery, in microfluidics 55
and robotics as well as in bioarchitecture for development of e.g. climate-adaptive shading 56
systems [1]. With regard to each application, different stimuli are relevant and, range e.g. from 57
temperature and relative humidity to light and radiation. In bioarchitecture, the passive humidity-58
3
driven shape change of cellulosic materials, like plants and wood, in reaction to changing 59
environmental, i.e. weathering, conditions is used for an energy-efficient conversion of primary 60
energy into a kinetic one. Consequently, it is in the nature of things, that these materials are 61
additionally exposed to elevated temperatures and ultraviolet (UV) light during service, and it is 62
of high relevance to characterize their thermal and radiation induced degradation behavior and 63
its effect on their long-term material properties with regard to adaptive or constructive applications 64
[2]. Since adaptivity to external stimuli, like temperature or relative humidity, is the condition for 65
an efficient technical usage of weathering conditions within bioarchitecture, mostly polymer-based 66
material systems, especially wood, are used for the development of so-called smart building skins 67
[3]. 68
In this context, Cottonid is a cellulose-based humidity-sensing material manufactured by the 69
parchmentizing process, which exhibits great potential for the production of climate-adaptive 70
elements with tailor-made material properties [4]. This study focusses the impact of solar radiation 71
on chemical structure and micromechanical properties of the cellulose-based humidity-sensing 72
material Cottonid. It is an extract of a comprehensive experimental study on the influence of 73
individual manufacturing parameters on the functional and mechanical properties of the 74
biopolymeric material by means of instrumented actuation and fatigue assessments. The results 75
are used for application-oriented structural optimization of Cottonid for adaptive or constructive 76
applications by adjustment of the manufacturing process. 77
The results presented were obtained by a combination of non-destructive analytical and 78
micromechanical investigations to build up a more profound knowledge about Cottonid’s 79
interaction with its environment and the effect of long-term exposure to weathering conditions on 80
its structure-property-relationships on the exposed surface. In the next step, the effect on the 81
macromechanical properties will be investigated by the help of instrumented quasi-static and 82
fatigue experiments. 83
1.1 Thermal and light-induced degradation mechanisms in polymeric materials 84
As stated above, the properties of polymer-based material systems are affected by environmental 85
effects and therefore extensive studies have been carried out in recent years on different 86
stabilization strategies to improve their long-term behavior in technical applications. To avoid 87
degradation, which manifests in e.g discoloration, pronounced decrease of mechanical properties 88
4
and embrittlement, especially the addition of photostabilizers supports reasonable lifetimes in 89
service, which in bioarchitecture means presence of elevated temperatures, changing degrees of 90
relative humidity, influence of oxygen and solar radiation, while predictability of service lifetimes 91
is the goal [5-7]. For cellulose, which is the most abundant biopolymer on earth and therefore 92
intensively used as raw material for various stimuli-responsive material systems, the mechanism 93
of photodegradation is induced by a superimposition of several radical reactions. An initial 94
reaction is a decrease in degree of polymerization (DP) caused by scission of cellulose chains 95
[8]. Yatagai and Zeronian investigated degradation mechanisms caused by ultraviolet (UV) 96
irradiation, heat exposure and by a combination of both treatments. They revealed changes in 97
color as well as formation of carbonyl, carboxyl and hydroperoxide groups, resulting in a decrease 98
in α-cellulose content and degree of polymerization (DP). It was stated, that heat exposure alone 99
caused reactions comparable to UV exposure [9]. Hon further observed a reaction of cellulosic 100
carbon free radicals with oxygen molecules in electron paramagnetic resonance (EPR) studies, 101
identifying oxygen as decisive reagent in photooxidative degradation of cellulose [10,11]. 102
In case of cellulose-based material systems, wood is one of the most important engineering and 103
structural materials. Infrared spectroscopy studies on wood exposed to UV irradiation observed 104
an increased amount of carboxylic and carbonyl chromophoric functional groups and a decreased 105
amount in aromatic functional groups, respectively. In these studies, mainly lignin-derived 106
degraded products could be observed on specimens’ surfaces. Nevertheless, as stated above, 107
degradation by sunlight or UV radiation, resulting in pronounced structural modifications, is also 108
expected for the other chemical components (cellulose, hemicelluloses). Though it could be 109
verified, that these reactions were limited to the surface [12]. Efficient methods for characterizing 110
these changes in chemical structure are Fourier transform infrared (FTIR) and electron 111
paramagnetic resonance (EPR) spectroscopy, whereas EPR gives information about evolution of 112
radicals related to radiation-induced degradation mechanisms and can be used to verify oxidation 113
reactions that cause deviations from the initial IR spectra [13,14]. 114
To characterize the impact of degradation mechanisms on the long-term behavior of cellulose-115
based material systems in bioarchitectural applications, a precise simulation of outdoor 116
weathering conditions has to be performed in the lab. Solar radiation envelopes a range from 117
200 to 2500 nm, where irradiance levels are present in the visible part. For polymers, the UV part 118
5
of the spectrum, which reaches the earth’s surface, is the most critical one [15]. Therefore, the 119
influence of short-wavelength visible radiation as well as thermal loads on the long-term material 120
properties in the already described application field is of high importance. Further, it is an 121
advantage for research, if aging experiments could be accelerated while simultaneously not 122
changing the temperature due to radiative energy input and hence keeping the causes for 123
degradation viz. temperature and radiation separated. On this topic, Baltscheit et al. [16] and 124
Hemmerich et al. [17,18] report on the simulation of the aging behavior of transparent materials 125
under accelerated artificial conditions with prioritizing effects under blue light radiation with short-126
wavelength and high energy. 127
1.2 Bioinspired, stimuli-responsive materials for bioarchitectural applications 128
In response to external stimuli, like temperature, relative humidity or light etc., stimuli-responsive 129
polymer-based material systems are able of autonomous reactions, e.g. adaptive shape 130
changing, which is an energy-efficient way of producing kinetic energy or a mechanical force due 131
to volume expansion. Therefore, nowadays in terms of energy-efficiency and eco-friendliness this 132
bio-inspired mechanism is very interesting for implementation in technical and engineering issues. 133
Applications fields are various and range from microfluidics over soft robotics to so-called 134
bioarchitectural topics, where smart building skins respond to changing weathering conditions 135
with adaptive reactions. E.g., with increasing temperature, single façade elements expand to 136
provide shading and shrink, when temperatures are decreasing again, so that they are not 137
permanently blocking the sight out of the building. In case of cellulose-based materials, like wood, 138
the decisive stimulus, which activates the adaptive reactions, is humidity. Due to hygroscopic 139
water uptake from the surrounding environment, cellulose micro fibrils swell perpendicular to their 140
orientation within the material and cause a passive shape change, whose magnitude and direction 141
is programmed in the microstructure [19]. This behavior can be observed for various plant 142
systems, where the microstructure of the cell walls is used for directed swelling and shrinking 143
processes [3,20]. These biological moving concepts have been an inspiration for the development 144
of a variety of bio-inspired actuators for different applications in recent years to introduce the 145
efficient relationship between structure and function by development of new functional materials 146
[21-23]. The available actuation concepts, like one-dimensional bending, which is realized over 147
bilayered systems, with one active and one passive layer with regard to the present stimulus, two-148
6
dimensional stretching, buckling or three-dimensional volume expansion, can be adjusted by the 149
microstructure of the polymer-based material systems and have their specific advantages and 150
disadvantages with respect to the indented application. Also, a combination of these deformation 151
modes in one actuator system is conceivable by microstructural tuning. Furthermore, the 152
development of systems that respond to multiple external stimuli in a smart and foreseeable way 153
is in the focus of current research [1,3,24]. Additionally, experiments with chemical degradation 154
of matrix polymers to retain just the more porous cellulose scaffold for functionalization have been 155
conducted. Besides usage of the dimensional instability when in contact with humidity in climate-156
adaptive building shells, the material behavior can also be used for production of curved timber 157
elements by specific upstream humidity treatment and intelligent combination of layers with 158
different micro fibril angles [19,25]. 159
Therefore, smart building skins play an important role in the required global reduction of energy 160
consumption, since autonomous, humidity-driven wood bilayers can serve as an energy-efficient 161
alternative to motor-driven façade shading elements [26]. To assess the performance of the 162
systems, especially the long-term stability as well as the repeatability of the humidity-driven 163
movements, instrumented test setups, which simulate outdoor weathering conditions have been 164
developed using environmental chambers and materials’ reactions have been characterized, e.g. 165
by optical monitoring of the swelling and shrinkage strains, measurements of changes in 166
temperature, moisture content or other material specific parameters. Furthermore, the effect of 167
different humidity cycles, slow and fast cycles in high and low humidity ranges, where 168
investigated. During these experiments, a hysteresis was observed, when strains are plotted as 169
function of relative humidity [27]. 170
1.3 Cottonid material system 171
Cellulose as most abundant biopolymer on earth and therefore a very sustainable resource is an 172
attractive material candidate for substitution of fossil products in specific, i.e. mostly functional, 173
applications as stated above. Besides native cellulose, cellulose derivates, like e.g. regenerated 174
or oxidized cellulose containing cellulose II crystals, are favored because of their simple and 175
reproducible way of manufacturing. For this material class, the amount of inter- and intramolecular 176
hydrogen bonds is very important for the physical properties of cellulosic commercial products 177
[28]. For the above rendered adaptive applications, pure cellulosic materials often show a more 178
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pronounced swelling and shrinking behavior in comparison to composite materials like wood. In 179
this case, Cottonid is a modified natural material fully based on partly modified cellulose and 180
appears to be a mix of cellulose I and II. Based on unsized raw paper, chemical modification is 181
achieved by a treatment with a warm zincdichloride (ZnCl2) or sulphuric acid (H2SO4) solution, 182
called parchmentizing. The temperature of the catalyst bath Tcat and the reaction time treact in it 183
define the amount of inter- and intramolecular hydrogen bonds that are newly formed [4]. These 184
are, as stated above, important for the final mechanical and physical properties. Since nowadays 185
this well known material gains new relevance in technical and especially climate-adaptive 186
applications, Scholz et al. performed an experimental assessment to qualify Cottonid in general 187
for technical applications compared to established materials, like synthetic plastics and wood [29-188
31], as well as to assess the influence of individual manufacturing parameters on the amount of 189
hydrogen bonds present and therefore on the functional and mechanical properties of Cottonid 190
[32-34]. Furthermore, the impact of outdoor weathering conditions on the long-term actuation and 191
fatigue behavior is characterized. The aim is to structurally optimize Cottonid [35] through 192
adjustment of the manufacturing process for the production of Cottonid elements with tailor-made 193
properties for either adaptive or constructive applications. 194
195
2. Materials and Methods 196
2.1 Sample preparation 197
For aging experiments, specimens were cut out of a plate of industrial Cottonid material (Ernst 198
Krueger, Geldern, Germany) with a thickness of tmat = 2.0 mm. 199
For actuation experiments, specimens were cut out of plates of the structurally optimized Cottonid 200
variant M60Z50 with material thicknesses of tmat,thin = 0.4 mm and tmat,thick = 4.0 mm. Unsized raw 201
paper (weight = 320 g/m2, tmat = 0.9 mm, Hahnemuehle, Dassel, Germany), which fully consists 202
of cotton linters, subsequently marked as "M", was used for the production of M60Z50. For 203
chemical treatment, a 70 wt-% zincdichloride (ZnCl2) solution, subsequently marked as "Z", is 204
used as catalyst. The sample name of the resulting Cottonid variants is a combination of the 205
chosen manufacturing parameters (Tab. 1). The samples are then smoothed and dried in a 206
calender (Sumet, Denklingen, Germany) under pressure and temperature. In order to prevent a 207
dimensional change of the material due to water absorption from the environment, the samples 208
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are stored under weight in a dry atmosphere until further analysis [33]. Caused by the 209
manufacturing process, the cellulose micro fibrils in the paper layers have a preferred orientation 210
in manufacturing direction [30]. So dependent on specimen location within the Cottonid sheet, 211
varying actuation and mechanical properties, respectively, are expected, Fig. 1a. Actuator type I 212
was chosen to characterize humidity-driven swelling and shrinking behavior perpendicular to 213
micro fibril axis, Fig. 1b. 214
For conditioning, specimens were stored under laboratory conditions (temperature T = 23 ± 2°C, 215
relative humidity φ = 35 ± 5%) for a time tcond > 48 hrs before testing. 216
2.2 Aging experiments 217
The aging experiments were performed under certain combinations of temperature T and relative 218
humidity φ, which especially in case of φ were dependent on the used device but not controllable. 219
So, the changes in material properties discussed in this study are only relevant for these special 220
environmental parameters. Differences can be expected if higher humidities and/or higher 221
temperatures had been used in both the heat and UV exposures [8]. 222
2.2.1 Short-wavelength blue light and temperature 223
Aging experiments under short-wavelength blue light were performed in a customized test setup 224
for accelerated optical aging of materials under predefined, constant conditions, developed by 225
[15-17]. The main component of the test setup is a double-wall specimen chamber out of high-226
quality steel, which is thermostatted by a continuous circulation of water and equipped with 227
thermocouples for the measurement of temperature in the chamber and on the specimens’ 228
surfaces. The cooling ensures, that specimens can be tempered between < 10°C and > 90°C 229
independent of the induced radiant power. For aging, a blue multi-chip-on-board high-230
performance LED (CLU048-1818C4-B455-XX, Citizen Electronics, Kamikurechi, Japan) is 231
mounted above the specimen. The irradiance on the specimens’ surfaces by the LED were 232
calculated using a raytracing simulation. By monitoring and saving of the operating parameters, 233
a controlled and traceable optical aging of specimens is realized [19]. 234
Industrially manufactured Cottonid specimens for aging experiments have a unique red color 235
intended as marketing and recognition factor for the product. The temperature on surface due to 236
absorbtion (of the blue LED light) was Taging ~75°C. Averaged irradiance was 12.8 kW/m2 for an 237
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aging time of taging = 3352 h. Relative humidity was measured directly after the LED was turned 238
off and was φLED ~56%. 239
To separate degradation mechanism due to thermal and radiative loading, respectively, further 240
specimens were thermally aged in an oven (UF 110 PLUS, Memmert, Schwabach, Germany) at 241
Taging = 75°C also for taging = 3352 h. Relative humidity was φoven ~0%. 242
2.2.2 Solar radiation 243
For simulation of solar radiation in the lab, in order to verify the comparability of LED irradiation 244
in the blue spectral region, further specimens were exposed to standardized artificial solar 245
radiation (CIE Solar ID65) in a commercial xenon weathering chamber (Suntest XLS+, Atlas, 246
Altenhasslau) with averaged irradiance of 2 kW/m2 for an aging time of taging = 3352 h. 247
Temperature was Taging = 75°C with a relative humidity of φsun ~11.2% 248
2.3 Structural investigations 249
2.3.1 Infrared and electron paramagnetic resonance spectroscopy 250
For analysis of changes in chemical structure due to thermal and light-induced degradation 251
mechanisms, FTIR spectroscopy was utilized (Nicolet iS50, Thermo Fisher Scientific, Waltham, 252
Massachusetts, USA). IR spectra after different durations of aging were obtained in the mid-IR 253
range of 4000 to 400 cm-1 in attenuated total reflection mode (ATR). Since the reflection mode 254
investigates the surface, a correlation with the ultra-micro-hardness measurements was possible. 255
Twenty scans were averaged at a resolution of 4 cm-1. A background scan was acquired for each 256
sample and subtracted in the subsequent measurement. The software offers the possibility to 257
correct the baseline drift and to automatically detect characteristic peaks. 258
For detection of organic radicals, which may form on the specimens’ surfaces due to thermal and 259
light-induced aging, electron paramagnetic resonance spectroscopy (EPR) (MiniScope MS 5000, 260
Bruker, Billerica, Massachusetts, USA) was carried out on specimens aged with the standardized 261
artificial solar irradiation (CIE Solar ID65). EPR spectra were obtained in a magnetic field range 262
of 330 to 340 mT at a microwave frequency of f = 9.438 GHz and five measurements were 263
averaged. 264
2.3.2 Surface roughness and ultra-micro-hardness testing 265
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Surface roughness of the specimens was assessed with the profile method according to DIN EN 266
ISO 4288 using a mobile surface roughness tester (MarSurf M 300 C, Mahr, Goettingen, 267
Germany). For each aging state, roughness values were calculated and averaged based on three 268
sampling lengths lr = 2.5 mm. 269
Instrumented ultra-micro-hardness measurements were performed using a dynamic ultra-micro-270
hardness tester (DUH 211, Shimadzu, Kyoto, Japan) and load-indentation depth curves were 271
obtained according to DIN EN ISO 14577. The process consists of a loading and unloading 272
phases, where the load is applied with a constant load rate up to a predetermined indentation 273
force of Fmax = 98.09 mN. For each series of tests, five indentations per sample were made for 274
each aging state. The change in Martens hardness ΔHM as well as indentation modulus Eit due 275
to thermal and light-induced degradation processes was calculated and related to the values in 276
initial condition. 277
2.4 Investigations on humidity-driven actuation behavior 278
For characterization of the humidity-driven swelling and shrinking behavior of the structurally 279
optimized Cottonid variant M60Z50, static actuation test were performed in an alternating climate 280
chamber (MKF 115, Binder, Tuttlingen, Germany) at a temperature Tclimate = 23°C and a relative 281
humidity φclimate = 95% for a swelling time of ts = 2.75 h, Fig. 2a. To allow for the hygroscopic 282
expansion of the Cottonid specimen, a customized specimen holder was used, where one clamp 283
is fixed and the other one is moveable, Fig. 2b. Actuation strains were measured using digital 284
image correlation (DIC) (Limess, Krefeld, Germany), for this the specimens’ surfaces were 285
speckled with a traceable pattern, Fig. 2c. For optical monitoring of the movements, an 286
encapsulated camera was used (Hero 5, GoPro, San Mateo, USA). 287
288
3. Results and Discussion 289
3.1 Infrared and electron paramagnetic resonance spectroscopy 290
Infrared spectra of the initial condition of Cottonid were depicted in relation to the aged states 291
thermal (Taging = 75°C for taging = 3352 h) in Fig. 3, optical (12.8 kW/m2 at Taging = 75°C for taging = 292
3352 h) in Fig. 4 and sun (2 kW/m2 at Taging = 75°C for taging = 3352 h) in Fig. 5. The spectra were 293
collected in a wavelength interval between 4,000 and 400 cm-1 and all of them show the 294
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characteristic peaks for cellulose, which are defined in the initial condition spectra. In the interval 295
between 3,600 and 3,100 cm-1 the stretching vibrations of the hydroxyl groups (ν(-OH)) of the 296
cellulose chains can be seen. The height and area of the peak provides information about inter- 297
and intramolecular hydrogen bonds present in the material. The much lower peak at 2,900 cm-1 298
is attributed to the stretching vibrations of the alkyle groups (ν(-CH)). Absorbed water is the reason 299
for the peak at 1,640 cm-1. In the interval between 1,300 and 900 cm-1 peaks of the alcohols 300
located on the cellulose chains can be observed. The peak of the glycosidic linkage, which is also 301
known as amorphous peak, can be found at 898 cm-1 [36]. 302
When comparing the spectrum in initial condition with the spectra of the different aging states it 303
becomes clear, that a considerable change in absorption can be detected at 2,900 cm-1 and 304
between 1,750 and 1,740 cm-1, respectively, which indicates the presence of oxidative stress on 305
the surface for all aging states. The close-ups of the interesting regions make the changes more 306
visible. The increase of peaks in the range of 1,750 and 1,740 cm -1 results from the formation of 307
carbonyl and carboxyl groups due to reactions with the surrounding oxygen. These reactions 308
imply the splitting of cellulose chains on the surface and a decrease of degree of polymerization 309
(DP) [8-10,37]. Therefore, the peak at 2,900 cm-1 simultaneously decreases because of these 310
oxidative reactions, indicating a degradation of C – H combinations. These findings could also be 311
verified by EPR spectroscopy, since formation of organic radicals could be detected with 312
increasing aging time, see Fig. 6 [13]. The described reactions are most pronounced for 313
specimens aged with the standardized artificial solar irradiation [8]. 314
Another reaction worth mentioning is the increase of the peak at 1,644 cm -1, which stands for 315
adsorbed water. At first, it is not reasonable, that a specimen aged with temperature and light 316
contains more water, since rather drying effects would be expected. Since the Cottonid specimens 317
were taken out of the experimental setups for aging to collect IR and EPR spectra, the authors 318
assume, that the material directly reacted with its surrounding again in taking up humidity from 319
the ambient air. 320
3.2 Roughness and ultra-micro-hardness testing 321
Fig. 7 shows the results of roughness measurements for the initial condition in comparison to the 322
different aging states. 323
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For evaluation of the change of surface roughness due to thermal and light-induced aging, 324
averaged roughness depth Rz and roughness value Ra were obtained. In general, the aged 325
specimens seem to have a lower roughness and especially when looking at Rz, a pronounced 326
difference is visible between initial and sun. This finding correlates with studies of Hauptmann et 327
al., where a decrease of nanoroughness of wood due to UV-irradiation accompanied by a change 328
in color was observed [38,39]. 329
Results of ultra-micro-hardness tests are depicted in Fig. 8. Here, just three aging stages are 330
shown since no results were available for the specimens aged with standardized artificial solar 331
irradiation (sun). A maximum test force of Fmax = 98.07 mN was chosen in order to evaluate an 332
influence of thermal and light-induced aging on the micromechanical properties in the outer layers 333
of the specimen. Fig. 8a displays load-displacement curves. Qualitatively, the aged specimens 334
exhibit lower values in indentation depths. Furthermore, differences in the slope of the loading 335
and unloading phase of each curve can be observed, which indicate a change in the elastic-336
plastic deformation behavior of the aged Cottonid specimens. For the purpose of comparability of 337
the characteristic values Martens hardness HM and indentation modulus Eit, Fig. 8b shows the 338
arithmetic mean and standard deviation of five measuring points for the initial condition, the 339
thermal and the optical aged state. By comparison, the different aging states show pronounced 340
differences within the characteristic values. Compared to the initial condition, thermally aged 341
specimens show a distinct increase of HM and Eit, which is also visible for the optically aged 342
specimens, but less pronounced. So, as expected, thermal and light-induced aging seems to lead 343
to an embrittlement of the outer, irradiated layers of the specimens, which can be verified by 344
several other studies on polymeric materials, especially wood [39]. 345
3.3 Humidity-driven actuation 346
Fig. 9 shows the results of static actuation tests (Tamb = 23°C, φamb = 95% r.H., ts = 2.75 h) on the 347
structurally optimized Cottonid variant M60Z50. True tangential strain ε’Tan, detected via DIC on 348
the specimens’ surfaces, is plotted over the swelling time ts and the influence of material thickness 349
tmat as well as cellulose micro fibril orientation on the humidity-driven swelling and shrinking 350
behavior is characterized. Strains parallel to cellulose micro fibril orientation (0°/X) are indexed 351
with x, whereas strains perpendicular to cellulose micro fibril orientation (90°/Y) are indexed with 352
y. 353
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In Fig. 9a, results are shown for M60Z50 specimens with tmat,thick = 4.0 mm and tmat,thin = 0.4 mm. 354
After a swelling time of ts = 0.25 h, ε’Tan,y,thin reaches its maximum with ~2.5% compared to ε’T,y,thick 355
with ~0.15%. So, while the thin specimen shows a very adaptive behavior, the thick one is more 356
or less dimensionally stable. At the end of the test at ts = 2.75 h ε’Tan,y,thick increases up to ~0.4% 357
compared to the initial condition. With regard to the thin specimen with ~2% at the end of the test, 358
this humidity-driven expansion is much lower. So it can be concluded, that humidity-driven 359
actuation behavior of Cottonid is a function of the material thickness tmat and therefore by varying 360
the amount of paper layers fed into the parchmentizing process either climate-adaptive elements 361
for bioarchitectural issues or dimensionally stable components for conventional constructive 362
issues can be produced. A transitional material thickness tmat,trans, where humidity-driven 363
expansions of Cottonid are not justifiable anymore with regard to standards for conventional 364
construction, will be defined in further investigations. 365
In Fig. 9b, showing results for the M60Z50 specimen with tmat,thin = 0.4 mm, it becomes clear, that 366
swelling due to water absorption is more pronounced perpendicular to cellulose micro fibril 367
orientation, since ε’Tan,y,thin reaches a higher value of ~2.5% compared to ε’Tan,x,thin = 1.5% after a 368
swelling time of ts = 0.25 h. After reaching its maximum value, ε’Tan,y,thin decreases again and 369
saturates after ts = 0.75 h at ~2%. At ts = 0.50 h, ε’Tan,x,thin reaches its maximum, saturates at 370
~2.25% and stays above ε’Tan,y,thin until the end of the test. It can be concluded, that for short 371
swelling times, the Y-orientation is favorable, while there seems to be no distinct difference in the 372
materials’ reaction when it comes to long-term humidity loading. 373
374
4. Conclusions and Outlook 375
This study, focusing on the impact of solar radiation on chemical structure and micromechanical 376
properties of the cellulose-based humidity-sensing material Cottonid, is an extract of a 377
comprehensive experimental study on the influence of individual manufacturing parameters on 378
the functional and mechanical properties of the biopolymeric material by means of instrumented 379
actuation and fatigue assessments. It could be shown, that the impact of thermal loads in 380
combination with solar radiation leads to chemical modifications of the cellulose on the surface of 381
the aged Cottonid specimens. Infrared spectra revealed changes in adsorption at 2,900 cm-1, i.e. 382
the spectral region of C - H stretching vibrations, and between 1,800 and 1,700 cm-1, i.e. the 383
spectral region of C = O stretching vibrations, and therefore indicate oxidative stress on the 384
14
surface of the aged specimens [4,8,9]. These findings are underlined with results of EPR 385
spectroscopy, which indicate the presence of oxidation-related radicals. The oxidative stress 386
obviously provokes a decreased surface roughness leading to embrittlement, which could be 387
verified by increased Martens hardness HM and indentation modulus Eit assessed by ultra-micro-388
hardness tests. Therefore, a change in micromechanical surface properties of the aged Cottonid 389
specimens due to chemical modifications induced by a combination of thermal loads and solar 390
irradiation could be observed [40-42]. Experiments with pure thermal loads induced comparable 391
degradation effects to combined loads, whereas aging with a standardized artificial solar 392
irradiation caused a more distinct material reaction compared to aging with short-wavelength blue 393
light radiation [14]. These more or less material-specific reactions onto the induced loads could 394
origin from the chemical modification of cellulose I in a not yet defined mix of cellulose I and II 395
during the manufacturing process of Cottonid and have to be thoroughly investigated in further 396
studies. Since for manufacturing of Cottonid the cellulose contained in the raw paper layers gets 397
partly hydrolyzed by the help of an chemical catalyst, which was observed to be a stabilizing 398
process in terms of light-induced radical reactions [8], these investigations will be of high interest 399
to qualify Cottonid for outdoor applications. Further, since the presented results were obtained on 400
industrial manufactured Cottonid material, which has a unique red color, it is essential to 401
investigate and comparatively evaluate photodegradation mechanisms on colorless, i.e. white, 402
Cottonid [8]. 403
Actuation tests on the structurally optimized Cottonid variant M60Z50 revealed an influence of the 404
material thickness tmat as well as of the predefined orientation of the cellulose micro fibrils. It can 405
be stated, that Cottonid’s actuation behavior is a function of its material thickness, i.e. a ten times 406
thinner specimen achieves a ten times increased humidity-driven expansion. Furthermore, 407
humidity-driven actuation is more pronounced perpendicular to micro fibril orientation, which is 408
already described in various studies concerning cellulose based materials [2,17,42]. These 409
findings can be used for the development of climate-adaptive Cottonid elements capable of 410
complex passive shape changes due to efficient and smart combination of microstructure and 411
material thickness. Since Cottonid is manufactured by chemical modification of single paper 412
layers, which are stacked to get thicker material, the adjustment and smart usage of these 413
manufacturing parameters for tailor-made climate-adaptive element production can be easily 414
implemented. 415
15
In summary, the conditions of the manufacturing process of Cottonid and its hygroscopic material 416
behavior make the material ideal for the development of application-oriented adaptive elements 417
capable of complex passive, humidity-driven shape changes with adjustable magnitude e.g. for 418
bioarchitectural issues. The aging experiments revealed an interaction of Cottonid with thermal 419
and light-induced loads, which are expected in natural weathering conditions, i.e. environmental 420
triggers, in this application field. The change in micromechanical properties and degradation 421
processes, respectively, on the surface have to be considered for the prediction of the long-term 422
behavior of climate-adaptive Cottonid elements. Up to now the results show, that degradation 423
takes place and that the modifications of the chemical structure also affect the micromechanical 424
properties. 425
In further studies, it will be investigated how these mechanisms affect the macroscopic 426
deformation behavior of Cottonid and its specific mechanical values, like Young’s modulus and 427
ultimate tensile strength, as well as the actuation behavior. For this, in a first step aging 428
experiments will be conducted at different temperatures and relative humidity levels to assess the 429
influence of weathering conditions on the degradation behavior. Furthermore, the customized 430
specimen holder for actuation experiments can be equipped with LEDs, so that in the near future 431
swelling and shrinking behavior can be characterized with superimposed thermal and light-432
induced loading. 433
434
Availability of data and materials 435
The datasets used and/or analyzed during the current study are available from the corresponding 436
author on reasonable request. 437
438
Competing interests 439
The authors declare that they have no competing interests. 440
441
Funding 442
16
The authors thank the German Research Foundation (Deutsche Forschungsgemeinschaft, DFG) 443
for funding the research project "Biomechanical qualification of the structure-optimized functional 444
material Cottonid as an adaptive element" (WA 1672/23-1, ZO 113/22-1). 445
446
Author contributions 447
R.S., M.L. and M.H. performed experiments, prepared figures and wrote the manuscript. F.W., 448
C.Z. and J.M. supervised the project. 449
450
Acknowledgements 451
The authors thank the Hahnmuehle FineArt GmbH (Dassel, Germany) and the Ernst Krueger 452
GmbH & Co. KG (Geldern, Germany) for providing raw material for Cottonid manufacturing and 453
industrial reference material. The assistance during lab work of Mr. T. Graszynski is greatfully 454
acknowledged. 455
456
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25
Tables 601
Tab. 1 602
Cottonid variant Cellulose source Reaction time Catalyst Temperature
M60Z50 Cotton linters
(„M“) 60 sec Zincdichloride
solution („Z“) 50 °C
603
26
Figure and table captions 604
Fig. 1 605
Specimen preparation for actuation experiments: a Specimen location in Cottonid sheet according 606
to manufacturing direction of paper layers, and b Cottonid actuator type I with speckled surface 607
for strain measurements via digital image correlation (DIC) mounted in customized specimen 608
holder 609
Fig. 2 610
a Test setup for actuation experiments in alternating climate chamber (MKF 115, Binder, 611
Tuttlingen, Germany); b Cottonid specimen with speckled surface for strain measurements via 612
digital image correlation (DIC) mounted in customized specimen holder; c Strain measurements 613
on specimen’s surface via DIC parallel (ε’Tan,x) and perpendicular (ε’Tan,y) to cellulose micro fibril 614
orientation 615
Fig. 3 616
Infrared (IR) spectra of industrial Cottonid material (Ernst Krueger): a In initial condition with peak 617
definition of raw material cellulose, and b Comparative evaluation of initial condition and after 618
thermal aging at ~75°C for taging = 3352 h; Peak evolution due to thermal aging: c Close-up at ṽ = 619
2.900 cm-1, and d Close-up at ṽ ~ 1.750 cm-1 620
Fig. 4 621
Infrared (IR) spectra of industrial Cottonid material (Ernst Krueger): a In initial condition with peak 622
definition of raw material cellulose, and b Comparative evaluation of initial condition and after 623
optical aging (blue LED-radiation, irradiance: 12,8 kW/h) for taging = 3352 h; Peak evolution due to 624
optical aging: c Close-up at ṽ = 2.900 cm-1, and d Close-up at ṽ ~ 1.750 cm-1 625
Fig. 5 626
Infrared (IR) spectra of industrial Cottonid material (Ernst Krueger): a In initial condition with peak 627
definition of raw material cellulose, and b Comparative evaluation of initial condition and after 628
optical aging (CIE solar ID65, irradiance: 2 kW/h) for taging = 3352 h; Peak evolution due to optical 629
aging: c Close-up at ṽ = 2.900 cm-1, and d Close-up at ṽ ~ 1.750 cm-1 630
27
Fig. 6 631
Electron paramagnetic resonance (EPR) spectra of industrial Cottonid material (Ernst Krueger) 632
in initial condition and after aging with standardized artificial solar irradiation (CIE solar ID65, 633
irradiance: 2 kW/h) for increasing aging times 634
Fig. 7 635
Roughness measurements on surface of industrial Cottonid material (Ernst Krueger) in different 636
aging stages 637
Fig. 8 638
Ultra-micro-hardness measurements on surface of industrial Cottonid material (Ernst Krueger) in 639
different aging stages: a Force (F) - indentation depth (h) curves, and b Obtained values for 640
Martens hardness HM and indentation modulus Eit 641
Fig. 9 642
Actuation tests on structurally optimized Cottonid variant M60Z50: a Influence of cellulose micro 643
fibril orientation, and b Influence of material thickness tmat 644
Tab. 1 645
Sample designation of structurally optimized Cottonid 646
647
648
Figures
Figure 1
Specimen preparation for actuation experiments: a Specimen location in Cottonid sheet according tomanufacturing direction of paper layers, and b Cottonid actuator type I with speckled surface for strainmeasurements via digital image correlation (DIC) mounted in customized specimen holder
Figure 2
a Test setup for actuation experiments in alternating climate chamber (MKF 115, Binder, Tuttlingen,Germany); b Cottonid specimen with speckled surface for strain measurements via digital imagecorrelation (DIC) mounted in customized specimen holder; c Strain measurements on specimen’s surfacevia DIC parallel (ε’Tan,x) and perpendicular (ε’Tan,y) to cellulose micro �bril orientation
Figure 3
Infrared (IR) spectra of industrial Cottonid material (Ernst Krueger): a In initial condition with peakde�nition of raw material cellulose, and b Comparative evaluation of initial condition and after thermalaging at ~75°C for taging = 3352 h; Peak evolution due to thermal aging: c Close-up at v = 2.900 cm-1,and d Close-up at v ~ 1.750 cm-1
Figure 4
Infrared (IR) spectra of industrial Cottonid material (Ernst Krueger): a In initial condition with peakde�nition of raw material cellulose, and b Comparative evaluation of initial condition and after opticalaging (blue LED-radiation, irradiance: 12,8 kW/h) for taging = 3352 h; Peak evolution due to optical aging:c Close-up at v = 2.900 cm-1, and d Close-up at v ~ 1.750 cm-1
Figure 5
Infrared (IR) spectra of industrial Cottonid material (Ernst Krueger): a In initial condition with peakde�nition of raw material cellulose, and b Comparative evaluation of initial condition and after opticalaging (CIE solar ID65, irradiance: 2 kW/h) for taging = 3352 h; Peak evolution due to optical aging: cClose-up at v = 2.900 cm-1, and d Close-up at v ~ 1.750 cm-1
Figure 6
Electron paramagnetic resonance (EPR) spectra of industrial Cottonid material (Ernst Krueger) in initialcondition and after aging with standardized arti�cial solar irradiation (CIE solar ID65, irradiance: 2 kW/h)for increasing aging times
Figure 7
Roughness measurements on surface of industrial Cottonid material (Ernst Krueger) in different agingstages
Figure 8
Ultra-micro-hardness measurements on surface of industrial Cottonid material (Ernst Krueger) in differentaging stages: a Force (F) - indentation depth (h) curves, and b Obtained values for Martens hardness HMand indentation modulus Eit
Figure 9
Actuation tests on structurally optimized Cottonid variant M60Z50: a In�uence of cellulose micro �brilorientation, and b In�uence of material thickness tmat